Optically induced resonant tunneling of electrons in nanostructures

Abstract: We developed the theory of elastic electron tunneling through a potential barrier driven by a strong high-frequency electromagnetic field. It is demonstrated that the driven barrier can be considered as a stationary two-barrier potential which contains the quasi-stationary electron states confined between these two barriers. When the energy of an incident electron coincides with the energy of the quasi-stationary state, the driven barrier becomes fully transparent for the electron (the resonant tunneling). The… Show more

“…It is worth noting that due to the mathematical similarity between the Helmholtz equation in the paraxial limit [1,2] and the Schrödinger equation [22], the typical phenomena of nonrelativistic quantum mechanics such as delay times and resonant tunneling can be readily simulated in an optics laboratory [23][24][25].…”

Angular Deviations, Lateral Displacements, and Transversal Symmetry Breaking: An Analytical Tutorial

“…It is worth noting that due to the mathematical similarity between the Helmholtz equation in the paraxial limit [1,2] and the Schrödinger equation [22], the typical phenomena of nonrelativistic quantum mechanics such as delay times and resonant tunneling can be readily simulated in an optics laboratory [23][24][25].…”

Angular Deviations, Lateral Displacements, and Transversal Symmetry Breaking: An Analytical Tutorial